US20240019126A1 - Injection manifold with tesla valves for rotating detonation engines - Google Patents
Injection manifold with tesla valves for rotating detonation engines Download PDFInfo
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- US20240019126A1 US20240019126A1 US18/372,796 US202318372796A US2024019126A1 US 20240019126 A1 US20240019126 A1 US 20240019126A1 US 202318372796 A US202318372796 A US 202318372796A US 2024019126 A1 US2024019126 A1 US 2024019126A1
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- 238000005474 detonation Methods 0.000 title claims description 37
- 238000002347 injection Methods 0.000 title description 67
- 239000007924 injection Substances 0.000 title description 67
- 238000002485 combustion reaction Methods 0.000 claims abstract description 128
- 239000000446 fuel Substances 0.000 claims abstract description 91
- 239000007800 oxidant agent Substances 0.000 claims abstract description 84
- 239000007789 gas Substances 0.000 claims abstract description 7
- 239000000203 mixture Substances 0.000 claims abstract description 6
- 238000009841 combustion method Methods 0.000 claims abstract description 3
- 238000000034 method Methods 0.000 claims description 20
- 239000000463 material Substances 0.000 claims description 5
- 238000004519 manufacturing process Methods 0.000 claims description 4
- 229910001069 Ti alloy Inorganic materials 0.000 claims description 3
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- 229910001026 inconel Inorganic materials 0.000 claims description 3
- 239000011858 nanopowder Substances 0.000 claims description 3
- 239000010935 stainless steel Substances 0.000 claims description 3
- 229910001220 stainless steel Inorganic materials 0.000 claims description 3
- 239000012530 fluid Substances 0.000 description 56
- 238000004891 communication Methods 0.000 description 24
- 239000003795 chemical substances by application Substances 0.000 description 11
- 238000013461 design Methods 0.000 description 4
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Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23R—GENERATING COMBUSTION PRODUCTS OF HIGH PRESSURE OR HIGH VELOCITY, e.g. GAS-TURBINE COMBUSTION CHAMBERS
- F23R7/00—Intermittent or explosive combustion chambers
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
- F02C5/00—Gas-turbine plants characterised by the working fluid being generated by intermittent combustion
- F02C5/02—Gas-turbine plants characterised by the working fluid being generated by intermittent combustion characterised by the arrangement of the combustion chamber in the chamber in the plant
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02K—JET-PROPULSION PLANTS
- F02K7/00—Plants in which the working fluid is used in a jet only, i.e. the plants not having a turbine or other engine driving a compressor or a ducted fan; Control thereof
- F02K7/02—Plants in which the working fluid is used in a jet only, i.e. the plants not having a turbine or other engine driving a compressor or a ducted fan; Control thereof the jet being intermittent, i.e. pulse-jet
- F02K7/06—Plants in which the working fluid is used in a jet only, i.e. the plants not having a turbine or other engine driving a compressor or a ducted fan; Control thereof the jet being intermittent, i.e. pulse-jet with combustion chambers having valves
- F02K7/067—Plants in which the working fluid is used in a jet only, i.e. the plants not having a turbine or other engine driving a compressor or a ducted fan; Control thereof the jet being intermittent, i.e. pulse-jet with combustion chambers having valves having aerodynamic valves
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02K—JET-PROPULSION PLANTS
- F02K9/00—Rocket-engine plants, i.e. plants carrying both fuel and oxidant therefor; Control thereof
- F02K9/42—Rocket-engine plants, i.e. plants carrying both fuel and oxidant therefor; Control thereof using liquid or gaseous propellants
- F02K9/44—Feeding propellants
- F02K9/52—Injectors
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23K—FEEDING FUEL TO COMBUSTION APPARATUS
- F23K2300/00—Pretreatment and supply of liquid fuel
- F23K2300/20—Supply line arrangements
Definitions
- the present disclosure generally relates to rotating detonation engines, and in particular, to a rotating detonation engine design with Tesla valves incorporated therein.
- RDE rotating detonation engine
- an RDE When an RDE is compared to a traditional internal combustion engine, e.g., a reciprocating engine, or a gas turbine engine, or liquid-fueled rocket engines, one can see higher thermal efficiencies and significantly smaller number of moving parts resulting in lighter and more robust designs.
- a traditional internal combustion engine e.g., a reciprocating engine, or a gas turbine engine, or liquid-fueled rocket engines
- an internal combustion chamber in the form of an inner cylindrical body, whereby fuel and an oxidizer, are injected therein from one or more annuluses formed between an outer cylindrical body and the inner cylindrical body (i.e., one for each of fuel and oxidizer), also referred to as injection manifolds, allowed to be mixed in the combustion chamber, combusted (detonated) and produce work.
- fuel and an oxidizer are injected therein from one or more annuluses formed between an outer cylindrical body and the inner cylindrical body (i.e., one for each of fuel and oxidizer), also referred to as injection manifolds, allowed to be mixed in the combustion chamber, combusted (detonated) and produce work.
- a combustion method includes the steps of mixing fuel and an oxidizer into a mixture, wherein fuel originates from a fuel manifold and the oxidizer originates from an oxidizer manifold, and combusting the mixture in a combustion chamber, the fuel manifold, the oxidizer manifold, and the combustion chamber forming parts of an injector assembly.
- Each of the fuel and oxidizer manifolds communicates with the combustion chamber via a plurality of dedicated radially disposed Tesla valves around the combustion chamber each via a corresponding port with only one Tesla valve between the fuel manifold and the corresponding port on the combustion chamber and with only one Tesla valve between the oxidizer manifold and the corresponding port on the combustion chamber, wherein the plurality of Tesla valves substantially eliminate reverse flow of exhaust gases from the combustion chamber back to the fuel manifold or the oxidizer manifold.
- a method of preventing reverse flow without any moving parts is also disclosed.
- the method consists of arranging a plurality of dedicated Tesla valves disposed between a first chamber and a second chamber each Tesla valve of the plurality of dedicated Tesla valves terminating at a port radially disposed around the second chamber, each Tesla valve of the plurality of dedicated Tesla valves having an inlet coupled to the first chamber and an outlet coupled to the second chamber via its corresponding port, and establishing a forward flow from the first chamber to the second chamber via the plurality of dedicated Tesla valves.
- the reverse flow is prevented from the second chamber to the first chamber without any moving parts.
- FIG. 1 is a perspective view of a rotating detonation engine (RDE) including a housing including an injector assembly.
- RDE rotating detonation engine
- FIG. 2 is a perspective view an injector assembly showing two sets of Tesla valves of Type I shown and discussed with respect to FIG. 3 A .
- FIGS. 3 A, 3 B, and 3 C are schematics of Tesla valves of Type I, Type II, and Type III, respectively.
- FIGS. 3 D, 3 E, and 3 F are schematics of Tesla valves showing flow patterns of Type I, Type II, and Type III, respectively.
- FIGS. 4 A, 4 B, and 4 C are schematics of port configuration for parallel-aligned, parallel-misaligned, and aligned series, where in each configuration ports coupled to fuel manifold and oxidizer manifold are provided according to the stated configuration.
- FIG. 5 is a perspective view of an injector assembly showing another configuration of port disposition wherein ports coupled to the fuel manifold and the oxidizer manifold are provided at an angled relationship.
- FIG. 6 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-aligned/Type II.
- FIG. 7 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-aligned/Type III.
- FIG. 8 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type I.
- FIG. 9 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type II.
- FIG. 10 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type III.
- FIG. 11 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type I.
- FIG. 12 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type II.
- FIG. 13 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type III.
- FIG. 14 is perspective view of an injector assembly wherein the port/Tesla valve configuration is angled/Type II.
- FIG. 15 is perspective view of an injector assembly wherein the port/Tesla valve configuration is angled/Type III.
- FIG. 16 is graphical representation of a simulation result showing the effectiveness of Tesla valves, according to the present disclosure.
- the term “about” can allow for a degree of variability in a value or range, for example, within 10%, within 5%, or within 1% of a stated value or of a stated limit of a range.
- the term “substantially” can allow for a degree of variability in a value or range, for example, within 90%, within 95%, or within 99% of a stated value or of a stated limit of a range.
- RDE rotating detonation engine
- CRDE continuous RDE
- a reverse flow preventer mechanism which can respond to the detonation wave dynamics requirements in order to eliminate or substantially reduce reverse flow into the injection manifolds.
- the RDE 100 includes a housing 102 and ports 104 and 106 for inputting fuel and oxidizers (ports for fuel, i.e., ports 104 are disposed on one side while ports for oxidizers, i.e., ports 106 are disposed on the opposite side).
- the housing 102 includes an inner cylindrical body 201 and an outer cylindrical body 202 , the space within the inner cylindrical body 201 forming a cylindrical annulus 204 that provides a combustion chamber, best shown in FIG. 2 , showing an example injector assembly 200 .
- the space between the inner cylindrical body 201 and the outer cylindrical body 202 forms two separated regions forming a fuel injection manifold 206 and an oxidizer injection manifold 208 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 201 forms the combustion chamber 204 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 2 two sets of such Tesla valves 210 and 212 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 204 via a port 214 .
- Tesla valves 210 are responsible for fluid communication between the fuel injection manifold 206 and the combustion chamber 204
- Tesla valves 212 are responsible for fluid communication between the oxidizer injection manifold 208 and the combustion chamber 204 .
- FIG. 2 provides a novel injection manifold design for rotation detonation engines (RDEs).
- RDEs rotation detonation engines
- high pressure ratio of detonation wave can cause reverse flow between the combustion chamber 204 and the fuel injection manifold 206 or the oxidizer injection manifold 208 due to the sudden pressure rise after the generation of the detonation wave.
- Reverse flow has been identified as one of the most critical issues in RDEs that are responsible for detonation wave propagation instability.
- Fluidic-controlled injectors which have minimal response time to detonation-induced back flow, can contribute to the overall flow and detonation stability by substantially eliminating reverse flow between the combustion chamber 204 and the fuel injection manifold 206 or the oxidizer injection manifold 208 .
- Tesla-valve-based injection manifolds have a fluidic reverse-resistive mechanism capable of suppressing detonation wave bifurcation and combination and thus enhancing stability.
- the fuel injection manifold 206 and the oxidizer injection manifold 208 have fluidic reverse-resistive mechanisms to mitigate against the reverse flow in the injector arrays caused by the high pressure behind the detonation wave.
- the fuel injection manifold 206 and the oxidizer injection manifold 208 with the aid of the Tesla valves 210 and 212 suppress reverse flow and thus enhance stability of RDEs.
- Injection manifolds with complex curved internal channels such as the Tesla-valve-based injectors described herein (see below for additional detail and designs) can be manufactured via a number of techniques, especially additive manufacturing, which can achieve high accuracy manufacturing using a variety of materials, such as metals stainless steel/oxidation-corrosion resistant alloys (e.g., INCONEL®)/titanium alloys/ceramics nanopowders, achieving a resolution of 20 ⁇ m.
- metals stainless steel/oxidation-corrosion resistant alloys e.g., INCONEL®
- Tititanium alloys/ceramics nanopowders achieving a resolution of 20 ⁇ m.
- Tesla valves each includes a fixed geometry passive check valve that allows a fluid to flow preferentially in one direction without any moving parts.
- the valves are structures that have a higher pressure drop for the flow in one direction (reverse) than the other (forward). Principals of fluid dynamics and momentum inertia allow the fluid to flow through a different flowpaths created by channel shape pattern and/or volume expansion/shrink in reverse direction. The high total pressure loss is caused by the fluid-to-wall and/or fluid-to-fluid (self) impingement.
- the Tesla valves include three types. These three types are shown in FIGS. 3 A- 3 C . It should be noted that the injector assembly shown in FIG. 2 , provides examples of Type-I shown in FIG. 3 A .
- the plurality of Tesla valve includes shapes selected form the group consisting of looped-shaped terminated with elongated ends (see FIG. 3 A ), an offset figure-8 shaped conduit terminated with elongated ends (see FIG. 3 B ), and a double spade-shaped conduit terminated with elongated ends (see FIG. 3 C ).
- a characteristic length Lc is shown in each of FIGS. 3 A, 3 B, and 3 C .
- the length Lc represents the length of the Tesla valve that is between a first chamber (e.g., a fuel or oxidizer manifold) and a second chamber (e.g., a combustion chamber).
- Type-I Tesla valve of FIG. 3 A is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction.
- Type-I includes a single loop pattern, wherein the loop is divided into two segments one longer than the other.
- Fluid flow i.e., fuel or oxidizer
- Substantially all of the fluid in the forward direction passes through the shorter loop segment towards the outlet.
- the reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet to the loop and advances through both segments of the loop.
- the reverse flow of the exhaust fluid (dashed lines) self-impinges on itself, thus preventing the exhaust fluid to advance to the inlet side.
- Type-II Tesla valve of FIG. 3 B is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction.
- Type-II includes a double loop pattern, wherein each loop of the double loop pattern is divided into two segments one longer than the other. Fluid flow (i.e., fuel or oxidizer) begins from the side identified as inlet and is shown as solid lines. Substantially all of the fluid in the forward direction passes through the shorter loop segment of each of the loops of the double loop configuration towards the outlet.
- the reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet toward the double loop and advances through both segments of each of the two loops.
- the reverse flow of the exhaust fluid self-impinges on itself at the end of the first loop (Loop 1) thus substantially preventing the exhaust fluid to advance beyond the first loop.
- Any amount of exhaust fluid that happened to escape the first loop enters the second loop (Loop 2) and again advances through both segments of the second loop (smaller arrows indicate a smaller residual flow in the second loop).
- the reverse flow of the exhaust fluid self-impinges on itself at the end of the second loop (Loop 2) thus substantially preventing the exhaust fluid to advance beyond the second loop towards the inlet.
- Type-III Tesla valve of FIG. 3 C is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction.
- Type-III includes a double spade-shape pattern. Fluid flow (i.e., fuel or oxidizer) begins from the side identified as inlet and is shown as solid lines. Substantially all of the fluid in the forward direction passes through the spade-shaped patterns towards the outlet. The reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet toward the two spade-shaped configuration and advances through both each.
- Fluid flow i.e., fuel or oxidizer
- the reverse flow of the exhaust fluid self-impinges on itself at the end of each spade-shaped patter thus substantially preventing the exhaust fluid to advance beyond the first spade (Spade 1). Any amount of exhaust fluid that happened to escape Spade 1 enters the second spade-shape pattern (Spade 2) wherein smaller arrows indicate a smaller residual flow in Spade 2.
- the reverse flow of the exhaust fluid self-impinges on itself at the end of Spade 2 thus substantially preventing the exhaust fluid to advance beyond Spade 2 towards the inlet.
- the Type-III valve creates a volume expansion to direct the majority of reverse flow to impinge on the wall. The fluid flows back to its original direction after impingement can further prevent the reverse flow.
- FIGS. 4 A- 4 C these valves can be configured according to at least 4 different configurations, shown in FIGS. 4 A- 4 C and FIG. 5 .
- FIG. 4 A presents a parallel-aligned configuration wherein the fuel and oxidizer ports form two parallel and aligned circles about the inner surface of the inner cylindrical body. This configuration is shown in FIG. 2 , as well.
- FIG. 4 B represents a parallel but misaligned configuration wherein the fuel and oxidizer ports form two parallel and misaligned circles about the inner surface of the inner cylindrical body.
- FIG. 4 C represents an aligned-series configuration wherein the fuel and oxidizer ports form a single aligned and series circle about the inner surface of the inner cylindrical body.
- FIG. 5 represents an angled configuration wherein the fuel and oxidizer ports and manifolds form angled relationship with one-another (90° shown, however, other angles are also possible).
- Type-I (see FIG. 3 A ) is shown in an angled configuration.
- an example of an injector assembly 500 is shown which includes an inner cylindrical body 501 and an outer cylindrical body 502 , the space within the cylindrical body 501 forming a cylindrical annulus 504 , that provides the combustion chamber.
- the space between the inner cylindrical body 501 and the outer cylindrical body 502 forms two separated regions forming a fuel injection manifold 506 and an oxidizer injection manifold 508 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 501 forms the combustion chamber 504 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 5 two sets of such Tesla valves 510 and 512 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 504 via a port 514 (for clarity the ports 514 are not shown on the inner surface of inner cylindrical body 501 ).
- Tesla valves 510 are responsible for fluid communication between the fuel injection manifold 506 and the combustion chamber 504
- Tesla valves 512 are responsible for fluid communication between the oxidizer injection manifold 508 and the combustion chamber 504 .
- the Tesla valves 510 and 512 are positioned in an angled configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 504 .
- FIGS. 6 - 15 various combinations of Tesla valve and the above-described configurations are shown. These various configurations while shown as individual instances, can be combined for additional tunability, e.g., a number of valves can be Tesla valve type-I and others Tesla valves type-II both in the same injector assembly. Alternatively, different configurations (see FIGS. 4 A- 4 C and 5 ) may be used in the same injector assembly.
- Type-II (see FIG. 3 B ) is shown in a parallel-aligned configuration (see FIG. 4 A ).
- an example of an injector assembly 600 is shown which includes an inner cylindrical body 601 and an outer cylindrical body 602 , the space within the cylindrical body 601 forming a cylindrical annulus 604 , that provides the combustion chamber.
- the space between the inner cylindrical body 601 and the outer cylindrical body 602 forms two separated regions forming a fuel injection manifold 606 and an oxidizer injection manifold 608 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 601 forms the combustion chamber 604 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 6 two sets of such Tesla valves 610 and 612 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 604 via a port 614 .
- Tesla valves 610 are responsible for fluid communication between the fuel injection manifold 606 and the combustion chamber 604
- Tesla valves 612 are responsible for fluid communication between the oxidizer injection manifold 608 and the combustion chamber 604 .
- the Tesla valves 610 and 612 are positioned in a parallel-aligned configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 604 .
- Type-III (see FIG. 3 C ) is shown in a parallel-aligned configuration (see FIG. 4 A ).
- an example of an injector assembly 700 is shown which includes an inner cylindrical body 701 and an outer cylindrical body 702 , the space within the cylindrical body 701 forming a cylindrical annulus 704 , that provides the combustion chamber.
- the space between the inner cylindrical body 701 and the outer cylindrical body 702 forms two separated regions forming a fuel injection manifold 706 and an oxidizer injection manifold 708 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 701 forms the combustion chamber 704 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 7 two sets of such Tesla valves 710 and 712 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 704 via a port 714 .
- Tesla valves 710 are responsible for fluid communication between the fuel injection manifold 706 and the combustion chamber 704
- Tesla valves 712 are responsible for fluid communication between the oxidizer injection manifold 708 and the combustion chamber 704 .
- the Tesla valves 710 and 712 are positioned in a parallel-aligned configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 704 .
- Type-I (see FIG. 3 A ) is shown in a parallel-misaligned configuration (see FIG. 4 B ).
- an example of an injector assembly 800 is shown which includes an inner cylindrical body 801 and an outer cylindrical body 802 , the space within the cylindrical body 801 forming a cylindrical annulus 804 , that provides the combustion chamber.
- the space between the inner cylindrical body 801 and the outer cylindrical body 802 forms two separated regions forming a fuel injection manifold 806 and an oxidizer injection manifold 808 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 801 forms the combustion chamber 804 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 8 one set of such Tesla valves 810 and 812 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 804 via a port 814 that are unlike previous embodiment are parallel but misaligned.
- Tesla valves 810 are responsible for fluid communication between the fuel injection manifold 806 and the combustion chamber 804
- Tesla valves 812 are responsible for fluid communication between the oxidizer injection manifold 808 and the combustion chamber 804 .
- the Tesla valves 810 and 812 are positioned in a parallel-misaligned configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 804 .
- Type-II (see FIG. 3 B ) is shown in a parallel-misaligned configuration (see FIG. 4 B ).
- an example of an injector assembly 900 is shown which includes an inner cylindrical body 901 and an outer cylindrical body 902 , the space within the cylindrical body 901 forming a cylindrical annulus 904 , that provides the combustion chamber.
- the space between the inner cylindrical body 901 and the outer cylindrical body 902 forms two separated regions forming a fuel injection manifold 906 and an oxidizer injection manifold 908 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 901 forms the combustion chamber 904 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 9 one set of such Tesla valves 910 and 912 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 904 via a port 914 that are parallel but misaligned.
- Tesla valves 910 are responsible for fluid communication between the fuel injection manifold 906 and the combustion chamber 904
- Tesla valves 912 are responsible for fluid communication between the oxidizer injection manifold 908 and the combustion chamber 904 .
- the Tesla valves 910 and 912 are positioned in a parallel-misaligned configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 904 .
- Type-III is shown in a parallel-misaligned configuration (see FIG. 4 B ).
- an example of an injector assembly 1000 is shown which includes an inner cylindrical body 1001 and an outer cylindrical body 1002 , the space within the cylindrical body 1001 forming a cylindrical annulus 1004 , that provides the combustion chamber.
- the space between the inner cylindrical body 1001 and the outer cylindrical body 1002 forms two separated regions forming a fuel injection manifold 1006 and an oxidizer injection manifold 1008 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1001 forms the combustion chamber 1004 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 10 one set of such Tesla valves 1010 and 1012 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1004 via a port 1014 that are parallel but misaligned.
- Tesla valves 1010 are responsible for fluid communication between the fuel injection manifold 1006 and the combustion chamber 1004
- Tesla valves 1012 are responsible for fluid communication between the oxidizer injection manifold 1008 and the combustion chamber 1004 .
- the Tesla valves 1010 and 1012 are positioned in a parallel-misaligned configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1004 .
- Type-I (see FIG. 3 A ) is shown in an aligned-series configuration (see FIG. 4 C ).
- an example of an injector assembly 1100 is shown which includes an inner cylindrical body 1101 and an outer cylindrical body 1102 , the space within the cylindrical body 1101 forming a cylindrical annulus 1104 , that provides the combustion chamber.
- the space between the inner cylindrical body 1101 and the outer cylindrical body 1102 forms two separated regions forming a fuel injection manifold 1106 and an oxidizer injection manifold 1108 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1101 forms the combustion chamber 1104 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 11 one set of such Tesla valves 1110 and 1112 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1104 via a port 1114 that are aligned and provided in series.
- Tesla valves 1110 are responsible for fluid communication between the fuel injection manifold 1106 and the combustion chamber 1104
- Tesla valves 1112 are responsible for fluid communication between the oxidizer injection manifold 1108 and the combustion chamber 1104 .
- the Tesla valves 1110 and 1112 are positioned in an aligned-series configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1104 .
- Type-II (see FIG. 3 B ) is shown in an aligned-series configuration (see FIG. 4 C ).
- an example of an injector assembly 1200 is shown which includes an inner cylindrical body 1201 and an outer cylindrical body 1202 , the space within the cylindrical body 1201 forming a cylindrical annulus 1204 , that provides the combustion chamber.
- the space between the inner cylindrical body 1201 and the outer cylindrical body 1202 forms two separated regions forming a fuel injection manifold 1206 and an oxidizer injection manifold 1208 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1201 forms the combustion chamber 1204 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 12 one set of such Tesla valves 1210 and 1212 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1204 via a port 1214 that are aligned and provided in series.
- Tesla valves 1210 are responsible for fluid communication between the fuel injection manifold 1206 and the combustion chamber 1204
- Tesla valves 1212 are responsible for fluid communication between the oxidizer injection manifold 1208 and the combustion chamber 1204 .
- the Tesla valves 1210 and 1212 are positioned in an aligned-series configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1204 .
- Type-II (see FIG. 3 B ) is shown in an aligned-series configuration (see FIG. 4 C ).
- an example of an injector assembly 1300 is shown which includes an inner cylindrical body 1301 and an outer cylindrical body 1302 , the space within the cylindrical body 1301 forming a cylindrical annulus 1304 , that provides the combustion chamber.
- the space between the inner cylindrical body 1301 and the outer cylindrical body 1302 forms two separated regions forming a fuel injection manifold 1306 and an oxidizer injection manifold 1308 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1301 forms the combustion chamber 1304 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 13 one set of such Tesla valves 1310 and 1312 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1304 via a port 1314 that are aligned and provided in series.
- Tesla valves 1310 are responsible for fluid communication between the fuel injection manifold 1306 and the combustion chamber 1304
- Tesla valves 1312 are responsible for fluid communication between the oxidizer injection manifold 1308 and the combustion chamber 1304 .
- the Tesla valves 1310 and 1312 are positioned in an aligned-series configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1304 .
- Type-II (see FIG. 3 B ) is shown in an angled configuration.
- an example of an injector assembly 1400 is shown which includes an inner cylindrical body 1401 and an outer cylindrical body 1402 , the space within the cylindrical body 1401 forming a cylindrical annulus 1404 , that provides the combustion chamber.
- the space between the inner cylindrical body 1401 and the outer cylindrical body 1402 forms two separated regions forming a fuel injection manifold 1406 and an oxidizer injection manifold 1408 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1401 forms the combustion chamber 1404 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 14 two sets of such Tesla valves 1410 and 1412 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1404 via a port 1414 (for clarity the ports 1414 are not shown on the inner surface of inner cylindrical body 1401 ).
- Tesla valves 1410 are responsible for fluid communication between the fuel injection manifold 1406 and the combustion chamber 1404
- Tesla valves 1412 are responsible for fluid communication between the oxidizer injection manifold 1408 and the combustion chamber 1404 .
- the Tesla valves 1410 and 1412 are positioned in an angled configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1404 .
- Type-II (see FIG. 3 B ) is shown in an angled configuration.
- an example of an injector assembly 1500 is shown which includes an inner cylindrical body 1501 and an outer cylindrical body 1502 , the space within the cylindrical body 1501 forming a cylindrical annulus 1504 , that provides the combustion chamber.
- the space between the inner cylindrical body 1501 and the outer cylindrical body 1502 forms two separated regions forming a fuel injection manifold 1506 and an oxidizer injection manifold 1508 , each in the form of a cylindrical annulus, although interchangeable.
- the space within the inner cylindrical body 1501 forms the combustion chamber 1504 , within which detonation occurs.
- Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves.
- FIG. 15 two sets of such Tesla valves 1510 and 1512 are shown, however, it should be appreciated a large number of the valves are disposed circumferentially about the two annuluses, each valve terminating into the combustion chamber 1504 via a port 1514 (for clarity the ports 1514 are not shown on the inner surface of inner cylindrical body 1501 ).
- Tesla valves 1510 are responsible for fluid communication between the fuel injection manifold 1506 and the combustion chamber 1504
- Tesla valves 1512 are responsible for fluid communication between the oxidizer injection manifold 1508 and the combustion chamber 1504 .
- the Tesla valves 1510 and 1512 are positioned in an angled configuration with respect to one-another bringing fuel and the oxidizer agent for combustion into the combustion chamber 1504 .
- FIG. 16 simulation results are provided to show the how the Type II and III operate in comparison to a conventional injection port.
- the shockwave from detonation works backward from the combustion chamber back to the injection manifold.
- the color blue represents 0% fuel (e.g., H 2 ) while the color red represents 100% fuel.
- the fuel is injected at the inlet where the majority of the inlet is occupied by the fuel.
- a significant amount of exhaust gases in the form of blue/green/yellow makes its way back to the inlet in the form of reverse flow.
- a characteristic length see FIGS.
- the Tesla valves can prevent reverse flow for a ratio of about 5 to about 35 of pressure (P 2 /P 1 ) from a second chamber (e.g., a combustion chamber) having pressure P 2 back to a first chamber (e.g., a fuel manifold or an oxidizer manifold) having pressure P 1 .
- a second chamber e.g., a combustion chamber
- a first chamber e.g., a fuel manifold or an oxidizer manifold
- Type II and Type II configurations shown in FIG. 16 very little exhaust gases return to the inlet.
- both types i.e., Type II and Type III
- no green is seen at the inlet as the majority of the exhaust gases are self-impinged at the corresponding Tesla valves.
- FIG. 16 provides evidence of operational theory of the Tesla valves discussed herein.
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Abstract
A combustion method is disclosed, which includes the steps of mixing fuel and an oxidizer into a mixture, wherein fuel originates from a fuel manifold and the oxidizer originates from an oxidizer manifold, and combusting the mixture in a combustion chamber, the fuel manifold, the oxidizer manifold, and the combustion chamber forming parts of an injector assembly wherein each of the fuel and oxidizer manifolds communicates with the combustion chamber via a plurality of dedicated radially disposed Tesla valves around the combustion chamber each via a corresponding port with only one Tesla valve between the fuel manifold and the corresponding port on the combustion chamber and with only one Tesla valve between the oxidizer manifold and the corresponding port on the combustion chamber, wherein the plurality of Tesla valves substantially eliminate reverse flow of exhaust gases from the combustion chamber back to the fuel manifold or the oxidizer manifold.
Description
- The present patent application is a continuation of U.S. Non-Provisional patent application Ser. No. 17/553,550, filed Dec. 16, 2021, now U.S. Pat. No. 11,767,979 to Liu et al., which is related to and claims the priority benefit of U.S. Provisional Patent Application Ser. No. 63/126,987, filed Dec. 17, 2020, the contents of each of which are hereby incorporated by reference in its entirety into the present disclosure
- None.
- The present disclosure generally relates to rotating detonation engines, and in particular, to a rotating detonation engine design with Tesla valves incorporated therein.
- This section introduces aspects that may help facilitate a better understanding of the disclosure. Accordingly, these statements are to be read in this light and are not to be understood as admissions about what is or is not prior art.
- In a conventional rotating detonation engine (RDE), fuel and an oxidizing agent are brought together in a detonation chamber where they are mixed and ignited via a pressure gain combustion process that is usually supersonic as is referred to as detonation.
- When an RDE is compared to a traditional internal combustion engine, e.g., a reciprocating engine, or a gas turbine engine, or liquid-fueled rocket engines, one can see higher thermal efficiencies and significantly smaller number of moving parts resulting in lighter and more robust designs.
- In a typical RDE, there exists an internal combustion chamber in the form of an inner cylindrical body, whereby fuel and an oxidizer, are injected therein from one or more annuluses formed between an outer cylindrical body and the inner cylindrical body (i.e., one for each of fuel and oxidizer), also referred to as injection manifolds, allowed to be mixed in the combustion chamber, combusted (detonated) and produce work.
- Once major issue with the RDEs is reverse flow into the injection manifold, which is caused by the high pressure behind the detonation wave. Such reverse flow is mainly responsible for detonation wave propagation instability owing to unwanted interruption of fuel and/or oxidizer flow. The propagation speed of detonation wave in RDEs is on the order of a few thousand of meters per second. Solutions such as mechanical check valve provide limited response time to the high-speed detonation wave propagation and are thus unsuitable.
- Therefore, there is an unmet need for a novel approach to address the reverse flow challenge into the injection manifolds in an RDE causing detonation wave propagation instability.
- A combustion method is disclosed, which includes the steps of mixing fuel and an oxidizer into a mixture, wherein fuel originates from a fuel manifold and the oxidizer originates from an oxidizer manifold, and combusting the mixture in a combustion chamber, the fuel manifold, the oxidizer manifold, and the combustion chamber forming parts of an injector assembly. Each of the fuel and oxidizer manifolds communicates with the combustion chamber via a plurality of dedicated radially disposed Tesla valves around the combustion chamber each via a corresponding port with only one Tesla valve between the fuel manifold and the corresponding port on the combustion chamber and with only one Tesla valve between the oxidizer manifold and the corresponding port on the combustion chamber, wherein the plurality of Tesla valves substantially eliminate reverse flow of exhaust gases from the combustion chamber back to the fuel manifold or the oxidizer manifold.
- A method of preventing reverse flow without any moving parts is also disclosed. The method consists of arranging a plurality of dedicated Tesla valves disposed between a first chamber and a second chamber each Tesla valve of the plurality of dedicated Tesla valves terminating at a port radially disposed around the second chamber, each Tesla valve of the plurality of dedicated Tesla valves having an inlet coupled to the first chamber and an outlet coupled to the second chamber via its corresponding port, and establishing a forward flow from the first chamber to the second chamber via the plurality of dedicated Tesla valves. The reverse flow is prevented from the second chamber to the first chamber without any moving parts.
- The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
-
FIG. 1 is a perspective view of a rotating detonation engine (RDE) including a housing including an injector assembly. -
FIG. 2 is a perspective view an injector assembly showing two sets of Tesla valves of Type I shown and discussed with respect toFIG. 3A . -
FIGS. 3A, 3B, and 3C are schematics of Tesla valves of Type I, Type II, and Type III, respectively. -
FIGS. 3D, 3E, and 3F are schematics of Tesla valves showing flow patterns of Type I, Type II, and Type III, respectively. -
FIGS. 4A, 4B, and 4C are schematics of port configuration for parallel-aligned, parallel-misaligned, and aligned series, where in each configuration ports coupled to fuel manifold and oxidizer manifold are provided according to the stated configuration. -
FIG. 5 is a perspective view of an injector assembly showing another configuration of port disposition wherein ports coupled to the fuel manifold and the oxidizer manifold are provided at an angled relationship. -
FIG. 6 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-aligned/Type II. -
FIG. 7 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-aligned/Type III. -
FIG. 8 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type I. -
FIG. 9 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type II. -
FIG. 10 is perspective view of an injector assembly wherein the port/Tesla valve configuration is parallel-misaligned/Type III. -
FIG. 11 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type I. -
FIG. 12 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type II. -
FIG. 13 is perspective view of an injector assembly wherein the port/Tesla valve configuration is aligned-series/Type III. -
FIG. 14 is perspective view of an injector assembly wherein the port/Tesla valve configuration is angled/Type II. -
FIG. 15 is perspective view of an injector assembly wherein the port/Tesla valve configuration is angled/Type III. -
FIG. 16 is graphical representation of a simulation result showing the effectiveness of Tesla valves, according to the present disclosure. - For the purposes of promoting an understanding of the principles of the present disclosure, reference will now be made to the embodiments illustrated in the drawings, and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of this disclosure is thereby intended.
- In the present disclosure, the term “about” can allow for a degree of variability in a value or range, for example, within 10%, within 5%, or within 1% of a stated value or of a stated limit of a range.
- In the present disclosure, the term “substantially” can allow for a degree of variability in a value or range, for example, within 90%, within 95%, or within 99% of a stated value or of a stated limit of a range.
- A novel approach is presented that addresses the reverse flow challenge into the injection manifolds in a rotating detonation engine (RDE, also known as continuous RDE or CRDE) causing detonation wave propagation instability. Towards this end, a reverse flow preventer mechanism is disclosed which can respond to the detonation wave dynamics requirements in order to eliminate or substantially reduce reverse flow into the injection manifolds.
- Referring to
FIG. 1 , a perspective view of anRDE 100 is shown. The RDE 100 includes ahousing 102 andports ports 104 are disposed on one side while ports for oxidizers, i.e.,ports 106 are disposed on the opposite side). Thehousing 102 includes an innercylindrical body 201 and an outercylindrical body 202, the space within the innercylindrical body 201 forming acylindrical annulus 204 that provides a combustion chamber, best shown inFIG. 2 , showing anexample injector assembly 200. The space between the innercylindrical body 201 and the outercylindrical body 202 forms two separated regions forming afuel injection manifold 206 and anoxidizer injection manifold 208, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 201 forms thecombustion chamber 204, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 2 , two sets of such Teslavalves combustion chamber 204 via aport 214. Teslavalves 210 are responsible for fluid communication between thefuel injection manifold 206 and thecombustion chamber 204, while Teslavalves 212 are responsible for fluid communication between theoxidizer injection manifold 208 and thecombustion chamber 204. - Thus, the approach shown in
FIG. 2 provides a novel injection manifold design for rotation detonation engines (RDEs). In conventional RDEs, high pressure ratio of detonation wave can cause reverse flow between thecombustion chamber 204 and thefuel injection manifold 206 or theoxidizer injection manifold 208 due to the sudden pressure rise after the generation of the detonation wave. Reverse flow has been identified as one of the most critical issues in RDEs that are responsible for detonation wave propagation instability. Fluidic-controlled injectors, which have minimal response time to detonation-induced back flow, can contribute to the overall flow and detonation stability by substantially eliminating reverse flow between thecombustion chamber 204 and thefuel injection manifold 206 or theoxidizer injection manifold 208. As such, Tesla-valve-based injection manifolds have a fluidic reverse-resistive mechanism capable of suppressing detonation wave bifurcation and combination and thus enhancing stability. Owing to theTesla valves fuel injection manifold 206 and theoxidizer injection manifold 208 have fluidic reverse-resistive mechanisms to mitigate against the reverse flow in the injector arrays caused by the high pressure behind the detonation wave. Thus thefuel injection manifold 206 and theoxidizer injection manifold 208 with the aid of theTesla valves - Injection manifolds with complex curved internal channels such as the Tesla-valve-based injectors described herein (see below for additional detail and designs) can be manufactured via a number of techniques, especially additive manufacturing, which can achieve high accuracy manufacturing using a variety of materials, such as metals stainless steel/oxidation-corrosion resistant alloys (e.g., INCONEL®)/titanium alloys/ceramics nanopowders, achieving a resolution of 20 μm.
- Tesla valves according to the present disclosure each includes a fixed geometry passive check valve that allows a fluid to flow preferentially in one direction without any moving parts. The valves are structures that have a higher pressure drop for the flow in one direction (reverse) than the other (forward). Principals of fluid dynamics and momentum inertia allow the fluid to flow through a different flowpaths created by channel shape pattern and/or volume expansion/shrink in reverse direction. The high total pressure loss is caused by the fluid-to-wall and/or fluid-to-fluid (self) impingement.
- The Tesla valves, according to the present disclosure include three types. These three types are shown in
FIGS. 3A-3C . It should be noted that the injector assembly shown inFIG. 2 , provides examples of Type-I shown inFIG. 3A . The plurality of Tesla valve includes shapes selected form the group consisting of looped-shaped terminated with elongated ends (seeFIG. 3A ), an offset figure-8 shaped conduit terminated with elongated ends (seeFIG. 3B ), and a double spade-shaped conduit terminated with elongated ends (seeFIG. 3C ). In each ofFIGS. 3A, 3B, and 3C a characteristic length Lc is shown. The length Lc represents the length of the Tesla valve that is between a first chamber (e.g., a fuel or oxidizer manifold) and a second chamber (e.g., a combustion chamber). - Referring to
FIG. 3D , the Type-I Tesla valve ofFIG. 3A is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction. Type-I includes a single loop pattern, wherein the loop is divided into two segments one longer than the other. Fluid flow (i.e., fuel or oxidizer) begins from the side identified as inlet and is shown as solid lines. Substantially all of the fluid in the forward direction passes through the shorter loop segment towards the outlet. The reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet to the loop and advances through both segments of the loop. The reverse flow of the exhaust fluid (dashed lines) self-impinges on itself, thus preventing the exhaust fluid to advance to the inlet side. - Referring to
FIG. 3E , the Type-II Tesla valve ofFIG. 3B is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction. Type-II includes a double loop pattern, wherein each loop of the double loop pattern is divided into two segments one longer than the other. Fluid flow (i.e., fuel or oxidizer) begins from the side identified as inlet and is shown as solid lines. Substantially all of the fluid in the forward direction passes through the shorter loop segment of each of the loops of the double loop configuration towards the outlet. The reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet toward the double loop and advances through both segments of each of the two loops. The reverse flow of the exhaust fluid (dashed lines) self-impinges on itself at the end of the first loop (Loop 1) thus substantially preventing the exhaust fluid to advance beyond the first loop. Any amount of exhaust fluid that happened to escape the first loop enters the second loop (Loop 2) and again advances through both segments of the second loop (smaller arrows indicate a smaller residual flow in the second loop). Again, the reverse flow of the exhaust fluid (dashed lines) self-impinges on itself at the end of the second loop (Loop 2) thus substantially preventing the exhaust fluid to advance beyond the second loop towards the inlet. - Referring to
FIG. 3F , the Type-III Tesla valve ofFIG. 3C is shown with flow pattern showing forward (solid lines) and reverse fluid flow (dashed lines) depicting pressure loss by fluid-to-fluid self-impingement in the reverse fluid direction. Type-III includes a double spade-shape pattern. Fluid flow (i.e., fuel or oxidizer) begins from the side identified as inlet and is shown as solid lines. Substantially all of the fluid in the forward direction passes through the spade-shaped patterns towards the outlet. The reverse flow of the exhaust is shown in dashed lines and moves from the side identified as outlet toward the two spade-shaped configuration and advances through both each. The reverse flow of the exhaust fluid (dashed lines) self-impinges on itself at the end of each spade-shaped patter thus substantially preventing the exhaust fluid to advance beyond the first spade (Spade 1). Any amount of exhaust fluid that happened to escapeSpade 1 enters the second spade-shape pattern (Spade 2) wherein smaller arrows indicate a smaller residual flow inSpade 2. Again, the reverse flow of the exhaust fluid (dashed lines) self-impinges on itself at the end ofSpade 2 thus substantially preventing the exhaust fluid to advance beyondSpade 2 towards the inlet. The Type-III valve creates a volume expansion to direct the majority of reverse flow to impinge on the wall. The fluid flows back to its original direction after impingement can further prevent the reverse flow. - In addition to the three types of Tesla Valves shown in
FIGS. 3A-3C , these valves can be configured according to at least 4 different configurations, shown inFIGS. 4A-4C andFIG. 5 .FIG. 4A presents a parallel-aligned configuration wherein the fuel and oxidizer ports form two parallel and aligned circles about the inner surface of the inner cylindrical body. This configuration is shown inFIG. 2 , as well.FIG. 4B represents a parallel but misaligned configuration wherein the fuel and oxidizer ports form two parallel and misaligned circles about the inner surface of the inner cylindrical body.FIG. 4C represents an aligned-series configuration wherein the fuel and oxidizer ports form a single aligned and series circle about the inner surface of the inner cylindrical body.FIG. 5 represents an angled configuration wherein the fuel and oxidizer ports and manifolds form angled relationship with one-another (90° shown, however, other angles are also possible). - With further reference to
FIG. 5 , Type-I (seeFIG. 3A ) is shown in an angled configuration. In this configuration, an example of aninjector assembly 500 is shown which includes an innercylindrical body 501 and an outercylindrical body 502, the space within thecylindrical body 501 forming acylindrical annulus 504, that provides the combustion chamber. The space between the innercylindrical body 501 and the outercylindrical body 502 forms two separated regions forming afuel injection manifold 506 and anoxidizer injection manifold 508, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 501 forms thecombustion chamber 504, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 5 , two sets ofsuch Tesla valves combustion chamber 504 via a port 514 (for clarity theports 514 are not shown on the inner surface of inner cylindrical body 501).Tesla valves 510 are responsible for fluid communication between thefuel injection manifold 506 and thecombustion chamber 504, whileTesla valves 512 are responsible for fluid communication between theoxidizer injection manifold 508 and thecombustion chamber 504. TheTesla valves combustion chamber 504. - Referring to
FIGS. 6-15 , various combinations of Tesla valve and the above-described configurations are shown. These various configurations while shown as individual instances, can be combined for additional tunability, e.g., a number of valves can be Tesla valve type-I and others Tesla valves type-II both in the same injector assembly. Alternatively, different configurations (seeFIGS. 4A-4C and 5 ) may be used in the same injector assembly. - In particular, with further reference to
FIG. 6 , Type-II (seeFIG. 3B ) is shown in a parallel-aligned configuration (seeFIG. 4A ). In this configuration, an example of aninjector assembly 600 is shown which includes an innercylindrical body 601 and an outercylindrical body 602, the space within thecylindrical body 601 forming acylindrical annulus 604, that provides the combustion chamber. The space between the innercylindrical body 601 and the outercylindrical body 602 forms two separated regions forming afuel injection manifold 606 and anoxidizer injection manifold 608, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 601 forms thecombustion chamber 604, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 6 , two sets ofsuch Tesla valves combustion chamber 604 via aport 614.Tesla valves 610 are responsible for fluid communication between thefuel injection manifold 606 and thecombustion chamber 604, whileTesla valves 612 are responsible for fluid communication between theoxidizer injection manifold 608 and thecombustion chamber 604. TheTesla valves combustion chamber 604. - With further reference to
FIG. 7 , Type-III (seeFIG. 3C ) is shown in a parallel-aligned configuration (seeFIG. 4A ). In this configuration, an example of aninjector assembly 700 is shown which includes an innercylindrical body 701 and an outercylindrical body 702, the space within thecylindrical body 701 forming acylindrical annulus 704, that provides the combustion chamber. The space between the innercylindrical body 701 and the outercylindrical body 702 forms two separated regions forming afuel injection manifold 706 and anoxidizer injection manifold 708, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 701 forms thecombustion chamber 704, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 7 , two sets ofsuch Tesla valves combustion chamber 704 via aport 714.Tesla valves 710 are responsible for fluid communication between thefuel injection manifold 706 and thecombustion chamber 704, whileTesla valves 712 are responsible for fluid communication between theoxidizer injection manifold 708 and thecombustion chamber 704. TheTesla valves combustion chamber 704. - With further reference to
FIG. 8 , Type-I (seeFIG. 3A ) is shown in a parallel-misaligned configuration (seeFIG. 4B ). In this configuration, an example of aninjector assembly 800 is shown which includes an innercylindrical body 801 and an outercylindrical body 802, the space within thecylindrical body 801 forming acylindrical annulus 804, that provides the combustion chamber. The space between the innercylindrical body 801 and the outercylindrical body 802 forms two separated regions forming afuel injection manifold 806 and anoxidizer injection manifold 808, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 801 forms thecombustion chamber 804, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 8 , one set ofsuch Tesla valves combustion chamber 804 via aport 814 that are unlike previous embodiment are parallel but misaligned.Tesla valves 810 are responsible for fluid communication between thefuel injection manifold 806 and thecombustion chamber 804, whileTesla valves 812 are responsible for fluid communication between theoxidizer injection manifold 808 and thecombustion chamber 804. Thus, theTesla valves combustion chamber 804. - With further reference to
FIG. 9 , Type-II (seeFIG. 3B ) is shown in a parallel-misaligned configuration (seeFIG. 4B ). In this configuration, an example of aninjector assembly 900 is shown which includes an innercylindrical body 901 and an outercylindrical body 902, the space within thecylindrical body 901 forming acylindrical annulus 904, that provides the combustion chamber. The space between the innercylindrical body 901 and the outercylindrical body 902 forms two separated regions forming afuel injection manifold 906 and anoxidizer injection manifold 908, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 901 forms thecombustion chamber 904, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 9 , one set ofsuch Tesla valves combustion chamber 904 via a port 914 that are parallel but misaligned.Tesla valves 910 are responsible for fluid communication between thefuel injection manifold 906 and thecombustion chamber 904, whileTesla valves 912 are responsible for fluid communication between theoxidizer injection manifold 908 and thecombustion chamber 904. Thus, theTesla valves combustion chamber 904. - With further reference to
FIG. 10 , Type-III (seeFIG. 3C ) is shown in a parallel-misaligned configuration (seeFIG. 4B ). In this configuration, an example of aninjector assembly 1000 is shown which includes an innercylindrical body 1001 and an outercylindrical body 1002, the space within thecylindrical body 1001 forming acylindrical annulus 1004, that provides the combustion chamber. The space between the innercylindrical body 1001 and the outercylindrical body 1002 forms two separated regions forming afuel injection manifold 1006 and anoxidizer injection manifold 1008, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1001 forms thecombustion chamber 1004, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 10 , one set ofsuch Tesla valves combustion chamber 1004 via aport 1014 that are parallel but misaligned.Tesla valves 1010 are responsible for fluid communication between thefuel injection manifold 1006 and thecombustion chamber 1004, whileTesla valves 1012 are responsible for fluid communication between theoxidizer injection manifold 1008 and thecombustion chamber 1004. Thus, theTesla valves combustion chamber 1004. - With further reference to
FIG. 11 , Type-I (seeFIG. 3A ) is shown in an aligned-series configuration (seeFIG. 4C ). In this configuration, an example of aninjector assembly 1100 is shown which includes an innercylindrical body 1101 and an outercylindrical body 1102, the space within thecylindrical body 1101 forming acylindrical annulus 1104, that provides the combustion chamber. The space between the innercylindrical body 1101 and the outercylindrical body 1102 forms two separated regions forming afuel injection manifold 1106 and anoxidizer injection manifold 1108, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1101 forms thecombustion chamber 1104, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 11 , one set ofsuch Tesla valves combustion chamber 1104 via aport 1114 that are aligned and provided in series.Tesla valves 1110 are responsible for fluid communication between thefuel injection manifold 1106 and thecombustion chamber 1104, whileTesla valves 1112 are responsible for fluid communication between theoxidizer injection manifold 1108 and thecombustion chamber 1104. Thus, theTesla valves combustion chamber 1104. - With further reference to
FIG. 12 , Type-II (seeFIG. 3B ) is shown in an aligned-series configuration (seeFIG. 4C ). In this configuration, an example of aninjector assembly 1200 is shown which includes an innercylindrical body 1201 and an outercylindrical body 1202, the space within thecylindrical body 1201 forming acylindrical annulus 1204, that provides the combustion chamber. The space between the innercylindrical body 1201 and the outercylindrical body 1202 forms two separated regions forming afuel injection manifold 1206 and anoxidizer injection manifold 1208, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1201 forms thecombustion chamber 1204, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 12 , one set ofsuch Tesla valves combustion chamber 1204 via aport 1214 that are aligned and provided in series.Tesla valves 1210 are responsible for fluid communication between thefuel injection manifold 1206 and thecombustion chamber 1204, whileTesla valves 1212 are responsible for fluid communication between theoxidizer injection manifold 1208 and thecombustion chamber 1204. Thus, theTesla valves combustion chamber 1204. - With further reference to
FIG. 13 , Type-II (seeFIG. 3B ) is shown in an aligned-series configuration (seeFIG. 4C ). In this configuration, an example of aninjector assembly 1300 is shown which includes an innercylindrical body 1301 and an outercylindrical body 1302, the space within thecylindrical body 1301 forming acylindrical annulus 1304, that provides the combustion chamber. The space between the innercylindrical body 1301 and the outercylindrical body 1302 forms two separated regions forming afuel injection manifold 1306 and anoxidizer injection manifold 1308, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1301 forms thecombustion chamber 1304, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 13 , one set ofsuch Tesla valves combustion chamber 1304 via aport 1314 that are aligned and provided in series.Tesla valves 1310 are responsible for fluid communication between thefuel injection manifold 1306 and thecombustion chamber 1304, whileTesla valves 1312 are responsible for fluid communication between theoxidizer injection manifold 1308 and thecombustion chamber 1304. Thus, theTesla valves combustion chamber 1304. - With further reference to
FIG. 14 , Type-II (seeFIG. 3B ) is shown in an angled configuration. In this configuration, an example of aninjector assembly 1400 is shown which includes an innercylindrical body 1401 and an outercylindrical body 1402, the space within thecylindrical body 1401 forming acylindrical annulus 1404, that provides the combustion chamber. The space between the innercylindrical body 1401 and the outercylindrical body 1402 forms two separated regions forming afuel injection manifold 1406 and anoxidizer injection manifold 1408, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1401 forms thecombustion chamber 1404, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 14 , two sets ofsuch Tesla valves combustion chamber 1404 via a port 1414 (for clarity theports 1414 are not shown on the inner surface of inner cylindrical body 1401).Tesla valves 1410 are responsible for fluid communication between thefuel injection manifold 1406 and thecombustion chamber 1404, whileTesla valves 1412 are responsible for fluid communication between theoxidizer injection manifold 1408 and thecombustion chamber 1404. TheTesla valves combustion chamber 1404. - With further reference to
FIG. 15 , Type-II (seeFIG. 3B ) is shown in an angled configuration. In this configuration, an example of aninjector assembly 1500 is shown which includes an innercylindrical body 1501 and an outercylindrical body 1502, the space within thecylindrical body 1501 forming acylindrical annulus 1504, that provides the combustion chamber. The space between the innercylindrical body 1501 and the outercylindrical body 1502 forms two separated regions forming afuel injection manifold 1506 and anoxidizer injection manifold 1508, each in the form of a cylindrical annulus, although interchangeable. The space within the innercylindrical body 1501 forms thecombustion chamber 1504, within which detonation occurs. Each of the two manifolds fluidly communicates with the combustion chamber via a plurality of Tesla valves. InFIG. 15 , two sets ofsuch Tesla valves combustion chamber 1504 via a port 1514 (for clarity theports 1514 are not shown on the inner surface of inner cylindrical body 1501).Tesla valves 1510 are responsible for fluid communication between thefuel injection manifold 1506 and thecombustion chamber 1504, whileTesla valves 1512 are responsible for fluid communication between theoxidizer injection manifold 1508 and thecombustion chamber 1504. TheTesla valves combustion chamber 1504. - Referring to
FIG. 16 , simulation results are provided to show the how the Type II and III operate in comparison to a conventional injection port. InFIG. 16 , in the conventional situation, it can be easily seen the shockwave from detonation works backward from the combustion chamber back to the injection manifold. In particular, the color blue represents 0% fuel (e.g., H2) while the color red represents 100% fuel. In the conventional example, the fuel is injected at the inlet where the majority of the inlet is occupied by the fuel. However, as seen a significant amount of exhaust gases in the form of blue/green/yellow makes its way back to the inlet in the form of reverse flow. According to the simulations, for a characteristic length (seeFIGS. 3A , 3B, and 3C) of about 20 mm, and passage diameter of about 1 mm, the Tesla valves can prevent reverse flow for a ratio of about 5 to about 35 of pressure (P2/P1) from a second chamber (e.g., a combustion chamber) having pressure P2 back to a first chamber (e.g., a fuel manifold or an oxidizer manifold) having pressure P1. - In Type II and Type II configurations shown in
FIG. 16 , however, very little exhaust gases return to the inlet. For example, in both types (i.e., Type II and Type III), no green is seen at the inlet as the majority of the exhaust gases are self-impinged at the corresponding Tesla valves. - Thus,
FIG. 16 provides evidence of operational theory of the Tesla valves discussed herein. - Those having ordinary skill in the art will recognize that numerous modifications can be made to the specific implementations described above. The implementations should not be limited to the particular limitations described. Other implementations may be possible.
Claims (18)
1. A combustion method within a rotating detonation engine (RDE), comprising:
mixing fuel and an oxidizer into a mixture, wherein fuel originates from a fuel manifold and the oxidizer originates from an oxidizer manifold; and
combusting the mixture in a combustion chamber, the fuel manifold, the oxidizer manifold, and the combustion chamber forming parts of an injector assembly
wherein each of the fuel and oxidizer manifolds communicates with the combustion chamber via a plurality of dedicated radially disposed Tesla valves around the combustion chamber each via a corresponding port with only one Tesla valve between the fuel manifold and the corresponding port on the combustion chamber and with only one Tesla valve between the oxidizer manifold and the corresponding port on the combustion chamber, wherein the plurality of Tesla valves substantially eliminate reverse flow of exhaust gases from the combustion chamber back to the fuel manifold or the oxidizer manifold.
2. The method of claim 1 , wherein the plurality of Tesla valve includes shapes of looped-shaped terminated with elongated ends.
3. The method of claim 2 , wherein the plurality of Tesla valves are disposed based on parallel-aligned wherein fuel and oxidizer ports form parallel and aligned outlets.
4. The method of claim 3 , wherein the plurality of Tesla valves are angled wherein the plurality of tesla valve are divided into pairs of Tesla Valves that are disposed at about 90°.
5. The method of claim 4 , wherein the injector assembly is manufactured by additive manufacturing.
6. The method of claim 5 , wherein the material used for the injector assembly includes material selected from the group consisting of nanopowders of stainless steel, INCONEL®, titanium alloys, and ceramics.
7. The method of claim 1 , wherein the injector assembly further comprises:
an inner cylindrical body space within which forming a combustion chamber, and an outer cylindrical body, wherein the space between the outer cylindrical body and the inner cylindrical body forming a cylindrical annulus.
8. The method of claim 7 , wherein the cylindrical annulus forms i) the fuel manifold, and
ii) the oxidizer manifold separated from the fuel manifold.
9. The method of claim 8 , wherein each of the Tesla valves terminate to a corresponding port disposed on an inner surface of the inner cylindrical body.
10. The method of claim 1 , wherein when the plurality of Tesla valves have a characteristic length of about 20 mm having a passage diameter of about 1 mm, reverse flow is prevented when pressure ratio between the combustion chamber and either of the fuel manifold or oxidizer manifold are between about 5 and 35.
11. A method of preventing reverse flow without any moving parts, consisting of:
arranging a plurality of dedicated Tesla valves disposed between a first chamber and a second chamber each Tesla valve of the plurality of dedicated Tesla valves terminating at a port radially disposed around the second chamber, each Tesla valve of the plurality of dedicated Tesla valves having an inlet coupled to the first chamber and an outlet coupled to the second chamber via its corresponding port; and
establishing a forward flow from the first chamber to the second chamber via the plurality of dedicated Tesla valves, whereby reverse flow is prevented from the second chamber to the first chamber without any moving parts.
12. The method of claim 11 , wherein the first chamber is one of a fuel manifold or an oxidizer manifold, and the second chamber is a combustion chamber, wherein fuel from the fuel manifold and an oxidizer from the oxidizer manifold are combined and combusted in the combustion chamber.
13. The method of claim 11 , wherein the plurality of Tesla valve includes shapes selected from the group consisting of looped-shaped terminated with elongated ends, an offset figure-8 shaped conduit terminated with elongated ends, a double spade-shaped conduit terminated with elongated ends, and a combination thereof.
14. The method of claim 13 , wherein the plurality of Tesla valves are disposed based on a disposition selected from the group consisting of parallel-aligned wherein the ports form parallel and aligned outlets, parallel-misaligned wherein the ports form parallel outlets where the alternating fuel and oxidizer ports are misaligned, aligned-series wherein the ports form outlets of alternating fuel and oxidizer ports, angled where the fuel and oxidizer ports are disposed at an angle with respect to one-another, and a combination thereof.
15. The method of claim 14 , wherein the angled Tesla valves are disposed at about 90°.
16. The method of claim 15 , wherein the plurality of Tesla valves are manufactured by additive manufacturing.
17. The method of claim 16 , wherein the material used for the plurality of Tesla valves includes material selected from the group consisting of nanopowders of stainless steel, INCONEL®, titanium alloys, and ceramics.
18. The method of claim 11 , wherein when the plurality of Tesla valves have a characteristic length of about 20 mm having a passage diameter of about 1 mm, reverse flow is prevented when pressure ratio between the second chamber and the first chamber is between about 5 and 35.
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CN113819491B (en) * | 2021-06-26 | 2022-07-26 | 中国人民解放军空军工程大学 | Return-preventing air inlet structure of rotary detonation combustion chamber |
CN113757725B (en) * | 2021-06-26 | 2022-08-02 | 中国人民解放军空军工程大学 | Rotary detonation combustion chamber modal control flow channel configuration |
CN115501994B (en) * | 2022-10-11 | 2023-08-22 | 山东科川节能环保科技有限公司 | Jet device capable of achieving efficient cyclone and backflow prevention jet |
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US1329559A (en) * | 1916-02-21 | 1920-02-03 | Tesla Nikola | Valvular conduit |
US2411798A (en) * | 1944-07-05 | 1946-11-26 | Arthur H Matthews | Gas turbine |
US5265636A (en) * | 1993-01-13 | 1993-11-30 | Gas Research Institute | Fluidic rectifier |
US9695654B2 (en) * | 2012-12-03 | 2017-07-04 | Halliburton Energy Services, Inc. | Wellhead flowback control system and method |
US20150059718A1 (en) * | 2013-08-30 | 2015-03-05 | GM Global Technology Operations LLC | Engine Crankcase Breathing Passage With Flow Diode |
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US10627111B2 (en) * | 2017-03-27 | 2020-04-21 | United Technologies Coproration | Rotating detonation engine multi-stage mixer |
US10436110B2 (en) * | 2017-03-27 | 2019-10-08 | United Technologies Corporation | Rotating detonation engine upstream wave arrestor |
US20180355795A1 (en) * | 2017-06-09 | 2018-12-13 | General Electric Company | Rotating detonation combustor with fluid diode structure |
US11236908B2 (en) * | 2018-10-24 | 2022-02-01 | General Electric Company | Fuel staging for rotating detonation combustor |
US11255544B2 (en) * | 2019-12-03 | 2022-02-22 | General Electric Company | Rotating detonation combustion and heat exchanger system |
WO2021146779A1 (en) * | 2020-01-24 | 2021-07-29 | Vujinovic Zoran | Pulse detonation jet engine (propulsor) vujin |
US11209164B1 (en) * | 2020-12-18 | 2021-12-28 | Delavan Inc. | Fuel injector systems for torch igniters |
CN113819491B (en) * | 2021-06-26 | 2022-07-26 | 中国人民解放军空军工程大学 | Return-preventing air inlet structure of rotary detonation combustion chamber |
CN113757725B (en) * | 2021-06-26 | 2022-08-02 | 中国人民解放军空军工程大学 | Rotary detonation combustion chamber modal control flow channel configuration |
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